DE7626465U1 - DEVICE FOR MEASURING HIGH TEMPERATURES - Google Patents

Description

SIEMENS AKTIENGESELLSCHAFT Our mark

Berlin and Munich - VPA 76 G 4515 BRD

Device for measuring high temperatures

j. The innovation relates to a device for measuring high

.?: Temperatures (greater than 16OO ⁰ C). The measurement of temperatures

y up to approx. I600 ⁰ C takes place almost without any problems with the help of thermal

elements. Over this temperature range also thermo-5 can elements be used until about 2200 ⁰ C in the form schutzgasbespülter sheathed thermocouples. Let temperatures above 2200 ^{° C.}

| · On the other hand, you can only determine yourself with pyrometric devices.

The innovation is therefore based on the object of a device; 10 to measure very high temperatures (greater than 160 ⁰ C) to create, which allow the use of problem-free and precisely working measuring devices. For this purpose, it is proposed according to the innovation that a closed oxide ceramic tube on the side facing the heat source, into which an energy-conducting element protrudes, serves as a heat sensor. That way you get. a temperature converter, since only the closed end of the oxide ceramic tube has to be brought into contact with the actual measuring temperature, while the new design ensures that the energy-conducting element located inside the oxide ceramic tube is only exposed to a significantly lower temperature. If the closed end of the oxide ceramic tube3 is heated by the medium to be measured, it begins to radiate ^{according to the Stefan-Boltzmann 1 law.} The inwardly directed radiation of the end face (bottom) of the oxide ceramic tube is picked up by the energy-conducting organ and can be directed to a remote detector.

Size 22 Un / 08/20/1976

7626465 02/09/78

"·" "" ■ VPA 76 G 4515 BRD

In order to protect the energy-conducting organ from damage by influx of excessively high temperatures, one can design the innovation Place a metal tube between the oxide ceramic tube and the energy-conducting element, taking into account the specific problems of each individual This can be solved by the selection of the type of metal and the dimensioning of the metal pipe used. The Intermediate metal pipe can also be cooled very easily. Furthermore, one can use the metal pipe to conduct energy Let the organ protrude so far that it functions as a diaphragm for the radiation falling on the heat-conducting organ takes over. It can thus be achieved that only the radiation from the base of the oxide ceramic tube reaches the energy-conducting organ and the part of the oxide ceramic tube which may radiate less intensely and with a greater wavelength is masked out will. This increases the measuring accuracy of the method, since the diaphragm ensures that the entire incident, detected radiation comes from zones of practically the same temperature. In order to increase the measurement signal, several energy-conducting Organs are embedded side by side in the oxide ceramic tube.

A particularly advantageous embodiment is obtained when the energy-conducting organ is designed as an optical waveguide, because this means that the radiation absorbed is qualitative and quantitative almost unaffected or only influenced to a manageable extent can be directed to a remote detector. As an energy-conducting organ, a Thermocouple can be used.

The innovation is based on the embodiment shown in the drawing explained in detail.

The single figure shows a longitudinal section through a Temperaturme ßvorrichtung with an optical waveguide as an energy-conducting organ.

The device consists of an oxide ceramic tube closed on one side 10, which can be exposed to very high temperatures without the use of protective gas, up to near its Melting point, since it is mechanically as good as not stressed.

7626465 02/09/78

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VPA 76 G 4515 BRD

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Oxide ceramics are available with the following melting points:

Al ₂ O ₃ 0 MgO-Al ₂ 0 Be ° 2 Mg ° 2 Zr Th

approx. 2000 ⁰ C Ii 2100 ⁰ C Il 2500 ⁰ C Il 2700 ⁰ C Il 2750 ⁰ C Il 3050 ⁰ C

An optical waveguide serves as the energy-conducting element 11.

its front end has been freed from its protective cover 13. The end face 12 of the optical waveguide is flat and at right angles to the longitudinal direction of the fiber. Between the oxide ceramic tube and the optical waveguide is a metal tube 14 arranged so that it the optical waveguide in the direction of the bottom 10a of the oxide ceramic tube towers. 16 with an insulating washer is referred to as heat protection and 17 with the metallic attachment, the at the same time is conductively connected to the metal tube 14 and, if necessary, can be acted upon by a cooling device.

1 figure

5 claims

7626465 02/09/78

Claims (5)

; J "" '' "'■' ■■! '· ■' VPA 76 G 4515 BRD - / + - Protection claims 1. Device for measuring high temperatures (greater than ¹ than 1600 ⁰ C), characterized in that a closed on the side facing the heat source oxide ceramic tube (10) serves as a heat sensor, into which an energy-conducting member (11) protrudes. 2. Apparatus according to claim 1, characterized in that between the oxide ceramic tube (10) and the energy-conducting element (11) a metal tube (14) is arranged. '10 3. Device according to claim 2, characterized in that the ■ metal tube (14) protrudes beyond the energy-conducting member (11) in the direction of j the bottom (10a) of the oxide ceramic tube (10). 4. Apparatus according to claim 1 or 2, characterized in that that the energy-conducting element (11) is designed as an optical waveguide is. 5. Apparatus according to claim 1 or 2, characterized in that the energy-conducting member (11) is designed as a thermocouple is. 7626465 02/09/78